WriteableBitmap.PixelBuffer Property


Gets an access for the direct buffer where each pixel of the WriteableBitmap is written to.

 property IBuffer ^ PixelBuffer { IBuffer ^ get(); };
IBuffer PixelBuffer();
public IBuffer PixelBuffer { get; }
var iBuffer = writeableBitmap.pixelBuffer;
Public ReadOnly Property PixelBuffer As IBuffer

Property Value

A reference to the pixel buffer.


This code example uses the PixelBuffer property of WriteableBitmap to write to its pixel content.

The C# example comes from a larger code sample—the SDK XAML images sample. The C# code shown is part of a transcoding scenario that eventually uses the WriteableBitmap as an Image.Source value, and displays the image.

The examples in the other languages are a little more scoped and/or self-contained.

using (IRandomAccessStream fileStream = await file.OpenAsync(Windows.Storage.FileAccessMode.Read)) 
    BitmapDecoder decoder = await BitmapDecoder.CreateAsync(fileStream); 
    // Scale image to appropriate size 
    BitmapTransform transform = new BitmapTransform() {  
        ScaledWidth = Convert.ToUInt32(Scenario4WriteableBitmap.PixelWidth), 
        ScaledHeight = Convert.ToUInt32(Scenario4WriteableBitmap.PixelHeight)
    PixelDataProvider pixelData = await decoder.GetPixelDataAsync( 
        BitmapPixelFormat.Bgra8, // WriteableBitmap uses BGRA format 
        ExifOrientationMode.IgnoreExifOrientation, // This sample ignores Exif orientation 

    // An array containing the decoded image data, which could be modified before being displayed 
    byte[] sourcePixels = pixelData.DetachPixelData(); 

    // Open a stream to copy the image contents to the WriteableBitmap's pixel buffer 
    using (Stream stream = Scenario4WriteableBitmap.PixelBuffer.AsStream()) 
        await stream.WriteAsync(sourcePixels, 0, sourcePixels.Length); 
// You'll need to add the Pictures Library capability to your Package.appxmanifest file.

// MainPage.xaml
<Image x:Name="anyExampleImage" Width="100" Height="100"/>

// pch.h
#include <winrt/Windows.Graphics.Imaging.h>
#include <winrt/Windows.Storage.Streams.h>
#include <winrt/Windows.UI.Xaml.Media.Imaging.h>
struct __declspec(uuid("905a0fef-bc53-11df-8c49-001e4fc686da")) IBufferByteAccess : ::IUnknown
    virtual HRESULT __stdcall Buffer(uint8_t** value) = 0;

// MainPage.h
struct MainPage : MainPageT<MainPage>
    Windows::Foundation::IAsyncAction ClickHandler(Windows::Foundation::IInspectable const&, Windows::UI::Xaml::RoutedEventArgs const&);
    Windows::UI::Xaml::Media::Imaging::WriteableBitmap m_writeableBitmap{ nullptr };

// MainPage.cpp
Windows::Foundation::IAsyncAction MainPage::ClickHandler(IInspectable const&, RoutedEventArgs const&)
    uint32_t scaledSize = 100;
    m_writeableBitmap = Windows::UI::Xaml::Media::Imaging::WriteableBitmap(scaledSize, scaledSize);

    Windows::Storage::StorageFolder picturesFolder{ Windows::Storage::KnownFolders::PicturesLibrary() };
    auto anyExampleImageFile{ co_await picturesFolder.GetFileAsync(L"anyexampleimage.png") };
    Windows::Storage::Streams::IRandomAccessStream fileStream{ co_await anyExampleImageFile.OpenAsync(Windows::Storage::FileAccessMode::Read) };
    auto decoder{ co_await Windows::Graphics::Imaging::BitmapDecoder::CreateAsync(fileStream) };

    // Scale the image to the appropriate size.
    Windows::Graphics::Imaging::BitmapTransform transform;

    Windows::Graphics::Imaging::PixelDataProvider pixelData{ co_await decoder.GetPixelDataAsync(
        Windows::Graphics::Imaging::BitmapPixelFormat::Bgra8, // WriteableBitmap uses BGRA format 
        Windows::Graphics::Imaging::ExifOrientationMode::IgnoreExifOrientation, // This sample ignores Exif orientation 
    ) };

    // An array containing the decoded image data, which could be modified before being displayed 
    winrt::com_array<uint8_t> sourcePixels{ pixelData.DetachPixelData() };

    // TECHNIQUE 1; QI for IBufferByteAccess.
    auto bufferByteAccess{ m_writeableBitmap.PixelBuffer().as<::IBufferByteAccess>() };
    uint8_t * pTargetBytes{ nullptr };
    // TECHNIQUE 2; use a C++/WinRT helper function (and delete the definition of IBufferByteAccess in pch.h).
    //uint8_t * pTargetBytes{ m_writeableBitmap.PixelBuffer().data() };

    for (auto & element : sourcePixels)
        *(pTargetBytes++) = element;

// pch.h
#include <robuffer.h>

// MainPage.xaml.cpp
auto writeableBitmap{ ref new Windows::UI::Xaml::Media::Imaging::WriteableBitmap(100, 100) };

::IUnknown* pUnk{ reinterpret_cast<IUnknown*>(writeableBitmap->PixelBuffer) };
Microsoft::WRL::ComPtr<Windows::Storage::Streams::IBufferByteAccess> bufferByteAccess;
HRESULT hr{ pUnk->QueryInterface(IID_PPV_ARGS(&bufferByteAccess)) };

byte *pBuffer{ nullptr };

// Now, write into the WriteableBitmap by using pBuffer. For example, make the first pixel red.
*pBuffer = 0xFF; ++pBuffer;
*pBuffer = 0xFF; ++pBuffer;
*pBuffer = 0x0; ++pBuffer;
*pBuffer = 0x0;



Use the Language picker (near the title) to choose a programming language for the code example.

The IBuffer returned by PixelBuffer can't be written to directly. But you can use language-specific techniques to write to the underlying pixel content in the buffer.

  • To access the pixel content from C# or Microsoft Visual Basic, you can use the WindowsRuntimeBufferExtensions.AsStream method to access the underlying buffer as a stream. This is shown in the C# code example.
  • To access the pixel content from C++/WinRT, you have three alternatives. As long as you're not using namespace winrt;, then you can include the SDK header file robuffer.h to bring in the definition of the IBufferByteAccess COM interface. However, since using namespace winrt; is very common, you can alternatively define the IBufferByteAccess interface in one place in your project (see the C++/WinRT code example to see how). Once IBufferByteAccess is defined, using either of those two techniques, you can query PixelBuffer for an instance of IBufferByteAccess. You then call the IBufferByteAccess::Buffer method to retrieve a pointer to the buffer of bytes that represents the pixel content. This is shown in the C++/WinRT code example. The third alternative (also shown in the C++/WinRT code example) is to avoid using IBufferByteAccess altogether by retrieving the uint8_t* that's returned from a helper function that you can call with WriteableBitmap.PixelBuffer().data().
  • To access the pixel content from C++/CX, you can query PixelBuffer for the IBufferByteAccess interface, which is a COM interface. Include robuffer.h. You can then call the the IBufferByteAccess::Buffer method to retrieve a pointer to the buffer of bytes that represents the pixel content. This is shown in the C++/CX code example.

Applies to

See also